U.S. patent number 4,163,915 [Application Number 05/817,924] was granted by the patent office on 1979-08-07 for electric motors or generators.
This patent grant is currently assigned to National Research Development Corporation. Invention is credited to William Fong.
United States Patent |
4,163,915 |
Fong |
August 7, 1979 |
Electric motors or generators
Abstract
A three-phase wave-wound electric motor or generator with
switched phase-winding parts for alternative voltage operation, one
such connection placing all the phase-winding parts in parallel for
low-voltage, specifically 110 volt operation. The phase-winding
parts are not identical in that one of each pair includes a "dummy
coil," that is a slot-position having no coil, or coils, included
in circuit for some or all the alternative connections. The
arrangement permits of an extra parallel connection compared with
corresponding conventional windings and also provides harmonic
suppression, reduction of magnetic noise and improvement of torque
for motors and improved transient performance and improved output
waveform for generators.
Inventors: |
Fong; William (Bristol,
GB2) |
Assignee: |
National Research Development
Corporation (London, GB2)
|
Family
ID: |
10316542 |
Appl.
No.: |
05/817,924 |
Filed: |
July 21, 1977 |
Foreign Application Priority Data
|
|
|
|
|
Jul 26, 1976 [GB] |
|
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31008/76 |
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Current U.S.
Class: |
310/198 |
Current CPC
Class: |
H02K
3/28 (20130101) |
Current International
Class: |
H02K
3/28 (20060101); H02K 003/00 () |
Field of
Search: |
;310/180,184,198,201-208
;318/768,773-777 ;322/90 |
References Cited
[Referenced By]
U.S. Patent Documents
Primary Examiner: Skudy; R.
Attorney, Agent or Firm: Larson, Taylor and Hinds
Claims
What I claim is:
1. A 3-phase alternating-current, single-pole-number, electric
machine having three double-layer wave-sound stator phase-windings,
each said phase-winding comprising an even number of similar but
not identical phase-winding parts, the odd-numbered ones of said
phase-winding parts differing from the even-numbered ones thereof
by the presence of a dummy coil in said odd-numbered ones of said
phase-winding parts, said phase-winding parts being connected
together alternatively for alternative voltage operation, one
alternative connection comprising parallel connection of all the
phase-winding parts for each phase-winding.
2. A 3-phase alternating current electric machine having a stator
wound with double-layer wave-wound coils forming three stator
phase-windings, each phase-winding comprising an even number of
phase-winding parts, said phase-winding parts being alternatively
connected together for alternative voltage operation, one
alternative connection comprising parallel connection of all the
phase-winding parts for each phase winding, at least for said
parallel connection each phase-winding part comprising the same
number of coils connected in circuit, odd-numbered ones of said
phase winding parts spanning stator slot positions locating a dummy
coil which is included in the winding sequence of said stator coils
but not included in circuit therewith.
3. An electric machine having a three-phase, wave winding
comprising a plurality of similar but not identical phase-winding
parts comprising coils, said parts being connected together
alternatively for alternative voltages, one such connection
providing an arrangement wherein all of said phase-winding parts
are connected in parallel, and said parts differing, one from
another, by the presence of a dummy coil in one of the said
parts.
4. An electric machine as claimed in claim 3, in which one
phase-winding part of every pair thereof includes a slot position
devoid of coils.
5. An electric machine as claimed in claim 4, in which said slot
position devoid of coils is substantially in the center of the said
phase-winding part.
6. An electric machine as claimed in claim 3, comprising, in each
phase, two phase-winding parts being adapted for connection
alternatively in series star/series delta/parallel delta.
7. An electric machine as claimed in claim 4, comprising, in each
phase, four phase-winding parts forming two said pairs, said four
parts adapted for connection together alternatively in 2-parallel
star/2-parallel delta/4-parallel delta.
8. An electric machine as claimed in claim 3, wherein phase-winding
parts which are adapted for connection together in said parallel
arrangement have resultant induced e.m.f.'s which are co-phasal but
differ in magnitude from one another.
9. An electric machine as claimed in claim 3, wherein phase-winding
parts which adapted for connection together in said parallel
arrangement have resultant induced e.m.f.'s which are equal in
magnitude but differ in phase one from another.
Description
This invention relates to electric motors and generators and
particularly to motors and alternators with balanced, three-phase
wave windings.
The object of the invention is to provide improved windings for
such machines capable of providing an additional voltage
rating.
Accordingly, the invention provides a machine having a three-phase,
wave winding comprising a plurality of similar, but not identical,
phase-winding parts, said parts being connected together
alternatively for alternative voltages, one such connection
providing the parallel arrangement of all said phase-winding parts
and said parts differing, one from another, by the presence of a
dummy coil.
By a dummy coil is meant a slot position containing no coil, or
coils, included in the circuit of the phase winding part concerned,
the slot position being bridged for the series connection of the
coils of the phase-winding part. Such dummy coil may be present,
physically, in the winding and excluded from circuit solely in the
parallel connection described, or it may be omitted physically from
the winding, in which case it is necessarily omitted in all of the
alternative connections of the windings. Advantageously the slot
position devoid of coils is substantially in the center of the
corresponding phase-winding part.
In order that the invention may be clearly understood and readily
carried into practice, two conventional windings and two
corresponding windings according to the invention will now be
described in detail, by way of example, with reference to the
accompanying drawings, in which:
FIG. 1 shows one phase-winding of a conventional 28-pole,
three-phase wave winding in 99 slots;
FIG. 2 shows one phase-winding of a corresponding 28-pole,
three-phase wave winding in 99 slots according to the
invention;
FIG. 3 shows one phase-winding of a conventional 32-pole,
three-phase wave winding in 126 slots;
FIG. 4 shows one phase-winding of a corresponding 32-pole,
three-phase wave winding in 126 slots according to the
invention.
FIG. 5 is a slot vector diagram for one phase of the 28-pole
winding shown in FIG. 1;
FIG. 6 is a slot vector diagram for one phase of the 32-pole
winding shown in FIG. 3.
FIG. 7 shows one phase-winding of an alternative 28-pole,
three-phase winding in 99 slots providing 2-parallel circuits;
and
FIG. 8 shows one phase-winding of an alternative 32-pole,
three-phase winding in 126 slots providing 4-parallel circuits.
A waVe winding is characterised by the equation:
where
S is the armature slot number;
"p" is the pole-pair number;
"y" is the winding pitch;
the signs signify (+) a retrogressive winding and (-) a progressive
winding; and
"a" is the number of plexes, which determines the number of
parallel paths of the winding.
A wave winding is invariably a double-layer winding and, if
single-turn coils are used, there will thus be only two conductors
per slot. Such windings are particularly suited for low-voltage
machines.
A typical, practical motor-alternator combination, frequently used
in marine service, comprises a 3-phase, 4-pole synchronous or
induction motor energised from a 3-phase, 50 HZ or 60 HZ mains
supply, driving a 32-pole or a 28-pole, 3-phase wave wound
alternator to provide, respectively, a 400 HZ or 420 HZ, 3-phase
output at, say, 380 volts. By using alternative star/delta
connections, the same alternator can have the dual-voltage rating,
in the example given, of 380/220 volts. Because of the wide
availability of 110 volt apparatus, it would be convenient, in the
machine combination described, to provide the further alternative
output voltage of 110 volts. This can readily be achieved in a
machine according to the present invention.
FIG. 1 is the connection diagram for phase-winding A of a
conventional 28-pole, 3-phase, simplex, retrogressive wave winding
in a 99-slot stator. The letters "T" and "B" denote "T" the top
coil-side slot location and "B" the bottom coil-side slot location.
Thus, the coil pitch is 3 slots (slot 1 to slot 4 and so on).
Evaluating Equation 1, above:
S=99 slots
p=14 pole-pairs
y=7
a=(+)1 and the winding is a retrogressive, single circuit
winding.
Assuming unit e.m.f. for every coil, the resultant e.m.f. of the
17-coil left-hand coil-sequence, between terminals 1 and 2, is
16.19 units. The resultant e.m.f. of the 16-coil right-hand
coil-sequence, between terminals 3 and 4, is 15.32 units. The two
resultant e.m.f.'s are co-phasal. The layer factor is 0.955 and the
pitch factor is 0.972. Phases B and C are symmetrically displaced
by 120.degree. mechanical, so that only consideration of the one
phase, phase A of FIG. 1, is necessary.
Analysis of the slot vectors on a 28-pole scale for the winding of
FIG. 1, starting with coil T1 and ending with coil T14 shows that
the slot vectors for the coil-sequence between terminals 1 and 2
are disposed symmetrically, one half of the slot vectors on each
side of the slot vector of coil T57, the 9th coil of the
coil-sequence, see FIG. 5.
FIG. 2 shows phase A of a 3-phase 28-pole wave winding in 99 slots
of generally similar form to that of FIG. 1 but differing in that,
firstly, coil T57 is excluded from the coil-sequence and, secondly,
the left hand coil-sequence between terminals 1 and 2, is connected
in parallel with the right-hand coil sequence, between terminals 3
and 4.
For the winding of FIG. 2, the coil-pitch is 3 slots (slot 1 to
slot 4 and so on) as for the winding of FIG. 1. Assuming unit
e.m.f. for each coil, the resultant e.m.f. of the left-hand
coil-sequence, between terminals 1 and 2, is 15.19 units and the
resultant e.m.f. of the right-hand coil-sequence, between terminals
3 and 4, is 15.32 units. The two resultant e.m.f.'s are co-phasal
and the average e.m.f. if 15.26 units.
The layer factor os 0.925, the pitch factor is 0.972 and the
winding factor is 0.899. Phases B and C are symmetrically displaced
by 120.degree. mechanical with respect to phase A shown.
In a practical alternator, connections from all terminals 1, 2, 3
and 4 are brought out to switching terminals to permit of the
further alternative parallel (delta) connection shown in FIG. 2.
Together with the series star/series delta connections used for the
winding of FIG. 1, the arrangement of FIG. 2 provides alternative
voltage outputs in the ratios 2.sqroot.3:2:1, that is 380/220/110
volts in the specific instance. Thus, a series star/series
delta/parallel delta connection can be provided (not shown).
FIG. 3 shows phase A of a conventional 32-pole, 3-phase wave
winding in 126 slots.
Evaluating Equation 1, above:
S=126 slots
p=16 pole-pairs
y=8
a=(-)2 and the winding is thus a progressive winding with 2
circuits per phase.
The coil-pitch is 4 slots (slot 1 to slot 5 and so on). Assuming
unit e.m.f. per coil, the resultant e.m.f. of the left half
coil-sequence, between terminals 1 and 2 and terminals 4 and 3 in
series, is 20.06 units. The resultant e.m.f. of the right half
coil-sequence, between terminals 5 and 6 and terminals 8 and 7 in
series, is also 20.06 units. The two resultant e.m.f.'s are
co-phasal. The layer factor is 0.955, the pitch factor is 1.0 and
the winding factor is 0.955. Phases B and C are symmetrically
disposed at 120.degree. mechanical separation with respect to phase
A, so that only phase winding A of FIG. 3 need be considered.
In the 2 circuit per phase arrangement of FIG. 3, four
coil-sequences in all are shown, respectively between terminals 1,
2; terminals 5, 6; terminals 3, 4 and terminals 7, 8. These
coil-sequences contain, respectively 10 coils, 10 coils, 11 coils
and 11 coils.
Analysing, now, the slot-vectors of the two 11-coil coil-sequences
on a 32-pole scale, it will be seen that the slot-vectors of five
coils are each symmetrically disposed with respect to the
slot-vectors of five other coils about the slot-vector
corresponding to coil T37 and coil T100, respectively, see FIG.
6.
FIG. 4 shows phase A of a modified 3-phase, 32-pole wave winding in
126 slots, according to the present invention, wherein the coils
T37 and T100 of the FIG. 3 arrangement are omitted from circuit in
the respective 11-coil coil-sequences, reducing them to 10-coil
coil-sequences.
As in the earlier figures, the letters "T" and "B" represent
"T"--top coil-sides and "B"--bottom coil-sides. The two dummy coils
are represented by rectangular blocks enclosing the coil-side slot
numbers. The winding of the invention provides the additional
4-circuit connection shown in FIG. 4 and the four circuits are
indicated by the Circuit No. numerals 1 to 4 beneath the respective
coil-sequences.
Assuming unit e.m.f. per coil, the resultant e.m.f. of each of
circuits No. 1 and No. 3 is 9.59 units. The resultant e.m.f. of
each of circuits No. 2 and No. 4 is 9.46 units. The resultant
e.m.f.'s of all four circuits are co-phasal and the average
resultant e.m.f.'s are 9.53 units.
The layer factor is 0.907, the pitch factor is 1.0 and the winding
factor is 0.907.
The three permissible connections of the windings: 2-parallel
star/2-parallel delta/4-parallel delta provides output, or supply
rating, voltages in the ratios 2.sqroot.3:2:1 or, in the specific
case, 380 volts/220 volts/110 volts.
The windings according to the invention, as exemplified by the
parallel-connected windings of FIG. 2 and FIG. 4 provide not only
the additional output, or supply, voltage rating described but, in
common with known multi-parallel circuit windings, provide harmonic
suppression, reduction of magnetic noise, and enhancement of
starting and running torque, when used as motor windings, or
provide improvement of transient performance and of output
waveform, when used as generator windings.
The use of dummy coils, as described, to permit of doubling of the
number of parallel circuits, reduces the winding factors by some 5%
in each of the two examples given with reference to FIGS. 2 and
4.
The dummy coils described may also be included in the Series
star/Series delta and 2-parallel star/2-parallel delta connections
of FIG. 2 and FIG. 4 respectively. The voltage ratings of the
winding with all coils in circuit are modified in consequence, so
that the obtainable ratings are in the ratios
(1.05.times.2.sqroot.3):(1.05.times.2):1 or, in the specific case,
400 volts:230 volts:110 volts, which may often be a more
advantageous voltage rating.
The 28-pole winding in 99 slots of FIG. 2 and the 32-pole winding
in 126 slots of FIG. 4 both have co-phasal induced e.m.f.'s in the
parallel branches of each phase-winding, as has been explained with
reference to FIG. 5 and FIG. 6, respectively, but slightly
different magnitudes.
There is an alternate multi-parallel circuit connection wherein the
fundamental e.m.f's induced in all the branches of each
phase-winding are equal in magnitude but differ slightly in
phase.
FIG. 7 shows the alternate arrangement by comparison with FIG. 2
and FIG. 8 shows the alternative arrangement by comparison with
FIG. 4.
In FIG. 7, as in FIG. 1 and FIG. 2, "T" denotes the Top and "B"
denotes the Bottom coil-side slot location. The pitch is 3
slots.
In the arrangement of FIG. 7, the connection of the left-hand coil
sequence are: terminal 1 to coil-side T1, coil side B53 to terminal
2, terminal 2 to terminal 4 omitting the slot position T.57 as the
9th coil, terminal 4 to coil side B63 and coil side T11 to terminal
3. The connections of the right-hand coil sequence are: terminal 5
to coil side T64, coil side B17 to terminal 6, terminal 6 to
terminal 8, terminal 8 to coil side B7 and coil side T54 to
terminal 7, there being no dummy coil. The two phase winding parts
are parallel between terminals 1/5 and terminals 3/7, as shown.
Assuming unit e.m.f. for every coil of the phase-winding, the
resultant e.m.f.'s of the left-hand and right-hand coil sequences
are both 15.26 units, but they differ in phase by 1.82.degree.
electrical. The winding factor is 0.899.
Parallel connection of the phase winding parts between terminals 1,
2, 4 and 3 and between terminals 5, 6, 8 and 7 is electrically
permissible, the resultant induced e.m.f. being no greater than
that arising from manufacturing tolerances in coil-side location or
lamination dissymmetry.
In the arrangement of FIG. 8, the connections of the first of the
four circuits are: terminal 1 to coil side T1, coil side B37 to
terminal 2, terminal 2 to terminal 4, terminal 4 to coil side B81
and coil side T45 to terminal 3. The connections of the second
circuit are: terminal 5 to coil side T41, coil side B77 to terminal
6, terminal 6 to terminal 8 omitting slot position T37, terminal 8
to coil side B33 and coil side T123 to terminal 7. The connections
of the third circuit are: terminal 9 to coil side T64, coil side
B100 to terminal 10, terminal 10 to terminal 12, terminal 12 to
coil side B18 and coil side T108 to terminal 11. The connections of
the fourth circuit are: terminal 13 to coil side T104, coil side
B14 to terminal 14, terminal 14 to terminal 16 omitting the slot
position T100, terminal 16 to coil side B96 and coil side T60 to
terminal 15.
Again assuming unit e.m.f. for every coil, the induced e.m.f. in
each of the four circuits is 9.53 units. The e.m.f.'s of circuit 1
and 3 are co-phasal and the e.m.f.'s of circuits 2 and 4 are
co-phasal but the first pair (circuits 1 and 3) differ in phase
from the second pair (circuits 2 and 4) by 2.86.degree. electrical.
Again, parallel connection of all four circuits between terminals
1/5/9/13 and terminals 3/7/11/15 is permissible. Such a connection
can be thus used to provide a 2-parallel star/2-parallel
delta/4-parallel delta configuration (not shown).
The slot-numbers, 99 slots and 126 slots, of the examples given
herein are low compared with slot-numbers which may be used in
practice. As a rule, the greater the slot-number, the smaller the
induced e.m.f. differences between parallel branches.
* * * * *